Process for producing fuel cell electrode, catalyst-coated membrane and membrane-electrode assembly

ABSTRACT

Disclosed are processes for producing a fuel cell electrode and a membrane electrode assembly. In one preferred embodiment, the process comprises (a) preparing a suspension of catalyst particles dispersed in a liquid medium containing a polymer dissolved or dispersed therein; (b) dispensing the suspension onto a primary surface of a substrate selected from an electronically conductive catalyst-backing layer (gas diffuser plate) or a solid electrolyte membrane; and (c) removing the liquid medium to form the electrode that is connected to or integral with the substrate, wherein the polymer is both ion-conductive and electron-conductive with an electronic conductivity no less than 10 −4  S/cm and ionic conductivity no less than 10 −5  S/cm and the polymer forms a coating in physical contact with the catalyst particles or coated on the catalyst particles.

FIELD OF THE INVENTION

This invention relates to a process for producing a fuel cell electrode, catalyst-coated membrane (CCM), and membrane-electrode assembly (MEA). The electrode featuring ion- and electro-conductive electro-catalyst composition, the CCM, and the MEA are particularly useful for proton exchange membrane-type fuel cells.

BACKGROUND OF THE INVENTION

The proton exchange membrane or polymer electrolyte membrane fuel cell (PEM-FC) has been a topic of highly active R&D efforts during the past two decades. The operation of a fuel cell normally requires the presence of an electrolyte and two electrodes, each comprising a certain amount of catalysts, hereinafter referred to as electro-catalysts. A hydrogen-oxygen PEM-FC uses hydrogen or hydrogen-rich reformed gases as the fuel while a direct-methanol fuel cell (DMFC) uses methanol solution as the fuel. The PEM-FC and DMFC, or other direct organic fuel cells, are collectively referred to as the PEM-type fuel cell.

A PEM-type fuel cell is typically composed of a seven-layered structure, including a central polymer electrolyte membrane for proton transport, two electro-catalyst layers on the two opposite sides of the electrolyte membrane in which chemical reactions occur, two gas diffusion layers (GDLs) or electrode-backing layers stacked on the corresponding electro-catalyst layers, and two flow field plates stacked on the GDLs. Each GDL normally comprises a sheet of porous carbon paper or cloth through which reactants and reaction products diffuse in and out of the cell. The flow field plates, also commonly referred to as bipolar plates, are typically made of carbon, metal, or composite graphite fiber plates. The bipolar plates also serve as current collectors. Gas-guiding channels are defined on a surface of a GDL facing a flow field plate, or on a flow field plate surface facing a GDL. Reactants and reaction products (e.g., water) are guided to flow into or out of the cell through the flow field plates. The configuration mentioned above forms a basic fuel cell unit. Conventionally, a fuel cell stack comprises a number of basic fuel cell units that are electrically connected in series to provide a desired output voltage. If desired, cooling and humidifying means may be added to assist in the operation of a fuel cell stack.

Several of the above-described seven layers may be integrated into a compact assembly, e.g., the membrane-electrode assembly (MEA). The MEA typically includes a selectively permeable polymer electrolyte membrane bonded between two electrodes (an anode and a cathode). A commonly used PEM is poly(perfluoro sulfonic acid) (e.g., Nafion® from du Pont Co.), its derivative, copolymer, or mixture. Each electrode typically comprises a catalyst backing layer (e.g., carbon paper) and an electro-catalyst layer disposed between a PEM layer and the catalyst backing layer. Hence, in actuality, an MEA may be composed of five layers: two catalyst backing, two electro-catalyst layers, and one PEM layer interposed between the two electro-catalyst layers. Most typically, the two electro-catalyst layers are coated onto the two opposing surfaces of a PEM layer to form a catalyst-coated membrane (CCM). The CCM is then pressed between a carbon paper layer (the anode backing layer) and another carbon paper layer (the cathode backing layer) to form an MEA. It may be noted that, some workers in the field of fuel cells refer a CCM as an MEA. Commonly used electro-catalysts include noble metals (e.g., Pt), rare-earth metals (e.g., Ru), and their alloys. Known processes for fabricating high performance MEAs involve painting, spraying, screen-printing and hot-bonding catalyst layers onto the electrolyte membrane and/or the catalyst backing layers.

An electro-catalyst is needed to induce the desired electrochemical reactions at the electrodes or, more precisely, at the electrode-electrolyte interfaces. The electro-catalyst may be a metal black, an alloy or a supported metal catalyst, for example, platinum supported on carbon. In real practice, an electro-catalyst can be incorporated at the electrode-electrolyte interfaces in PEM fuel cells by applying it in a layer on either an electrode substrate (e.g., a surface of a carbon paper-based backing layer) or a surface of the membrane electrolyte. In the former case, electro-catalyst particles are typically mixed with a liquid to form a slurry or ink, which is then applied to the electrode substrate. While the slurry preferably wets the substrate surface to some extent, it must not penetrate too deeply into the substrate, otherwise some of the catalyst will not be located at the desired membrane-electrode interface. In the latter case, electro-catalyst particles are coated onto the two primary surfaces of a membrane to form a catalyst-coated membrane (CCM).

Electro-catalyst sites must be accessible to the reactants (e.g., hydrogen on the anode side and oxygen on the cathode side), electrically connected to the current collectors, and ionically connected to the electrolyte membrane layer. Specifically, electrons and protons are typically generated at the anode electro-catalyst. The electrons generated must find a path (e.g., the backing layer and a current collector) through which they can be transported to an external electric circuit. The protons generated at the anode electro-catalyst must be quickly transferred to the electrolyte (PEM) through which they migrate to the cathode. Electro-catalyst sites are not productively utilized if the protons do not have a means for being quickly transported to the ion-conducting electrolyte. For this reason, coating the exterior surfaces of the electro-catalyst particles and/or electrode backing layer (carbon paper or fabric) with a thin layer of an ion-conductive ionomer has been used to increase the utilization of electro-catalyst exterior surface area and increase fuel cell performance by providing improved ion-conducting paths between the electro-catalyst surface sites and the electrolyte membrane. Such an ion-conductive ionomer is typically the same material used as the PEM in the fuel cell. An ionomer is an ion-conducting polymer, which can be of low, medium or high molecular weight. For the case of a PEM fuel cell, the conducting ion is the proton and the ionomer is a proton-conducting polymer. The ionomer can be incorporated in the catalyst ink or can be applied on the catalyst-coated substrate afterwards. This approach has been followed by several groups of researchers, as summarized in the following patents:

-   1) D. P. Wilkinson, et al., “Impregnation of micro-porous     electro-catalyst particles for improving performance in an     electrochemical fuel cell,” U.S. Pat. No. 6,074,773 (Jun. 13, 2000). -   2) J. Zhang, et al., “Ionomer impregnation of electrode substrate     for improved fuel cell performance,” U.S. Pat. No. 6,187,467 (Feb.     13, 2001). -   3) I. D. Raistrick, “Electrode assembly for use in a solid polymer     electrolyte fuel cell,” U.S. Pat. No. 4,876,115 (Oct. 24, 1989). -   4) M. S. Wilson, “Membrane catalyst layer for fuel cells,” U.S. Pat.     No. 5,211,984 (May 18, 1993). -   5) J. M. Serpico, et al., “Gas diffusion electrode,” U.S. Pat. No.     5,677,074 (Oct. 14, 1997). -   6) M. Watanabe, et al., “Gas diffusion electrode for electrochemical     cell and process of preparing same,” U.S. Pat. No. 5,846,670 (Dec.     8, 1998). -   7) T. Kawahara, “Electrode for fuel cell and method of manufacturing     electrode for fuel cell,” U.S. Pat. No. 6,015,635 (Jan. 18, 2000). -   8) S. Hitomi, “Solid polymer electrolyte-catalyst composite     electrode, electrode for fuel cell, and process for producing these     electrodes,” U.S. Pat. No. 6,344,291 (Feb. 5, 2002). -   9) S. Hitomi, et al. “Composite catalyst for solid polymer     electrolyte-type fuel cell and process for producing the same,” U.S.     Pat. No. 6,492,295 (Dec. 10, 2002).

However, this prior-art approach of ionomer impregnation into the electrode layer and/or onto electro-catalyst particle surfaces has a serious drawback in that the ionomer, although ion-conducting (proton-conducting), is not electronically conducting. This is due to the consideration that a proton-exchange membrane, when serving as the solid electrolyte layer, cannot be an electronic conductor; otherwise, there would be internal short-circuiting, resulting in fuel cell failure and possible fire hazard. Such an electronically non-conductive material, when coated onto the surface of a catalyst particle or carbon paper fiber, will render the catalyst particle or carbon fiber surface electronically non-conductive. This would prevent the electrons generated at the catalyst sites from being quickly collected by the anode electrode substrate layer and the current collector, thereby significantly increasing the Ohmic resistance and reducing the fuel cell performance.

A measure of the fuel cell performance is the voltage output from the cell for a given current density. Higher performance is associated with a higher voltage output for a given current density or higher current density for a given voltage output. More effective utilization of the electro-catalyst, particularly through optimizing the electron and ion transfer rates, enables the same amount of electro-catalyst to induce a higher rate of electrochemical conversion in a fuel cell resulting in improved performance. This was the main object of the present invention.

SUMMARY OF THE INVENTION

The present invention provides a process for producing a fuel cell electrode featuring an electro-catalyst composition that comprises (a) a catalyst un-supported or supported on an electronically conducting solid carrier; and (b) an ion-conductive and electron-conductive coating material in physical contact with the catalyst, coated on the catalyst, and/or coated on a surface of the carrier, wherein the coating material has an electronic conductivity no less than 10⁻⁴ S/cm and ion conductivity no less than 10⁻⁵ S/cm. Preferably, the electronic conductivity is no less than 10⁻² S/cm and the ion proton conductivity is no less than 10⁻³ S/cm. The catalyst may be selected from transition metals, alloys, mixtures, and oxides that can be made into nano-scaled particles that stand alone or are supported on a conducting material such as carbon black.

In one preferred embodiment, the presently invented process comprises (a) preparing a suspension of catalyst particles dispersed in a liquid medium containing a polymer dissolved or dispersed therein; (b) dispensing the suspension onto a primary surface of a substrate selected from an electronically conductive catalyst-backing layer (gas diffuser plate) or a solid electrolyte membrane; and (c) removing the liquid medium to form the electrode that is connected to or integral with the substrate, wherein the polymer is both ion-conductive and electron-conductive. This polymer substantially constitutes the coating material that helps to establish two intertwine networks of charge transport paths, one for electrons and the other for ions (which are protons or hydroxide ions in a PEM-type fuel cell).

In the case of a solid electrolyte membrane (PEM layer) serving as the substrate, this process acts to deposit a desirable catalyst composition to form a layer of catalytic electrode onto a first primary surface of the PEM layer. The process may further comprise a step of depositing another layer of catalytic electrode to a second primary surface of the PEM layer (typically opposite to the first primary surface) to form a catalyst-coated membrane (CCM). The process further includes the step of sandwiching the CCM between two gas diffuser layers (GDLs) to form a membrane-electrode assembly (MEA). This process can be a continuous, roll-to-roll process for the mass production of MEAs at a low cost.

In the case of a gas diffuser layer (a first GDL) serving as the substrate, this process (steps (a)-(c)) acts to deposit a catalytic electrode onto a primary surface of the first GDL which supports this electrode layer. The process may further comprise a step of depositing a catalytic electrode to a primary surface of a second GDL and another step of sandwiching a PEM layer between the electrode layer of the first GDL and the electrode layer of the second GDL to form an MEA. Again, this process can be a continuous, roll-to-roll process for the mass production of MEAs at a low cost.

Preferably, the coating material comprises a polymer which is an ion- and electron-conductive polymer or a mixture of a proton-conducting polymer and an electron-conducting polymer.

The proton-conducting polymer may be selected from the group consisting of poly(perfluoro sulfonic acid), sulfonated polytetrafluoroethylene, sulfonated perfluoroalkoxy derivatives of polytetrafluoroethylene, sulfonated polysulfone, sulfonated poly(ether ketone), sulfonated poly(ether ether ketone), sulfonated polystyrene, sulfonated polyimide, sulfonated styrene-butadiene copolymers, sulfonated poly chloro-trifluoroethylene (PCTFE), sulfonated perfluoroethylene-propylene copolymer (FEP), sulfonated ethylene-chlorotrifluoroethylene copolymer (ECTFE), sulfonated polyvinylidenefluoride (PVDF), sulfonated copolymers of polyvinylidenefluoride with hexafluoropropene and tetrafluoroethylene, sulfonated copolymers of ethylene and tetrafluoroethylene (ETFE), polybenzimidazole (PBI), their chemical derivatives, copolymers, blends and combinations thereof.

The electrically conducting polymer may comprise a polymer selected from the group consisting of sulfonated polyaniline, sulfonated polypyrrole, sulfonated poly thiophene, sulfonated bi-cyclic polymers, their derivatives, and combinations thereof. These polymers are themselves also good proton-conductive materials.

Another preferred embodiment of the present invention is a process of producing a fuel cell electrode on a substrate selected from a gas diffuser layer (e.g., carbon paper or cloth) or a solid electrolyte membrane. The process comprises (a) preparing a first suspension or solution of a first liquid medium containing a first ion- and electron-conductive polymer dissolved or dispersed therein (but containing no catalyst); (b) dispensing this first suspension or solution onto the substrate and removing the first liquid to form a layer of first conductive polymer adhered to the substrate; and (c) depositing a catalyst composition onto the first conductive polymer with the catalyst composition being bonded to, mixed with or integral with the first conductive polymer to form the electrode. This electrode is characterized in that it comprises catalyst particles coated with or in physical contact with a conductive phase comprising the first conductive polymer and that this conductive phase has an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm. This step of depositing a catalyst composition may comprise (i) dispensing a second suspension of a second liquid medium with catalyst particles dispersed therein and a second ion- and electron-conductive polymer dissolved or dispersed therein and (ii) removing the second liquid to form the catalyst composition wherein the second conductive polymer has an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm. This second conductive polymer may be the same material as the first conductive polymer. Alternatively, this second conductive polymer may be mixed with the first conductive polymer during the deposition step to form the cited conductive phase.

Alternatively, this step of depositing a catalyst composition may comprise (i) dispensing a second suspension of a second liquid medium with a molecular metal precursor dispersed or dissolved therein and a second ion- and electron-conductive polymer dissolved or dispersed therein and (ii) converting the precursor to catalyst particles and removing the second liquid to form the catalyst composition wherein the second conductive polymer has an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm. This second conductive polymer may be the same material as the first conductive polymer. Alternatively, this second conductive polymer may be mixed with the first conductive polymer during the deposition step to form the cited conductive phase.

The incorporation of such an electro-catalyst composition (featuring bi-networks of charge transport paths) in a fuel cell electrode, catalyst-coated membrane, or membrane electrode assembly leads to much improved fuel cell performance with much reduced Ohmic loss, higher catalyst utilization efficiency, and higher cell output voltage (given the same desired operating current density).

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 Schematic of a prior-art PEM fuel cell electrode structure.

FIG. 2 Schematic of another prior-art PEM fuel cell electrode structure.

FIG. 3 A three-material model for a local catalyst-electrolyte-carbon fiber region in a prior-art fuel cell electrode.

FIG. 4 Schematic of an electrode structure according to a preferred embodiment of the present invention.

FIG. 5 The electron and proton conductivities of an ion-conductive and electron-conductive polymer mixture.

FIG. 6 The polarization curves of two fuel cells, one containing electrode catalyst particles coated with an ion- and electron-conductive polymer blend and the other containing electrode catalyst particles coated with ion-conductive (but not electron-conductive) polymer (Nafion).

FIG. 7 The polarization curves of two fuel cells, one containing electrode catalyst particles coated with an ion- and electron-conductive polymer (sulfonated polyaniline) and the other containing electrode catalyst particles coated with ion-conductive (but not electron-conductive) polymer (Nafion).

FIG. 8 (a) Schematic of a preferred embodiment of the invented process for producing a membrane-electrode assembly on a continuous basis; (b) Another preferred embodiment of the invented process for producing a membrane-electrode assembly on a continuous basis; and (c) A preferred embodiment of the invented process for producing a catalyst-coated membrane.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

A hydrogen-oxygen PEM-FC using hydrogen gas as the fuel and oxygen as the oxidant may be represented by the following electrochemical reactions:

Anode:H₂→2H⁺+2e⁻  (Eq.(1))

Cathode:½O₂+2H⁺+2e⁻→H₂O  (Eq.(2))

Total reaction:H₂+½O₂→H₂O  (Eq.(3))

Both electrode reactions proceed only on a three-phase interface which allows the reception of gas (hydrogen or oxygen) and the delivery or reception of proton (H⁺) and electron (e⁻) at the same time. An example of the electrode having such a function is a solid polymer electrolyte-catalyst composite electrode comprising a solid polymer electrolyte and catalyst particles. FIG. 1 schematically shows the structure of such a prior art electrode. This electrode is a porous electrode comprising catalyst particles 21 and a solid polymer electrolyte 22 three-dimensionally distributed in admixture and having a plurality of pores 23 formed thereinside. The catalyst particles form an electron-conductive channel, the solid electrolyte forms a proton-conductive channel, and the pore forms a channel for the supply and discharge of oxygen, hydrogen or water as product. The three channels are three-dimensionally distributed and numerous three-phase interfaces which allow the reception or delivery of gas, proton (H⁺) and electron (e⁻) at the same time are formed in the electrode, providing sites for electrode reaction. In this diagram, reference numeral 24 represents an ion-exchange membrane (typically the same material as the solid polymer electrolyte 22) while numeral 25 represents carbon or graphite fibers in a sheet of carbon paper as a catalyst backing layer.

The preparation of an electrode having such a structure has heretofore been accomplished typically by a process that comprises (a) preparing a paste of catalyst particles and, optionally, poly tetrafluoroethylene (PTFE) particles dispersed in a liquid, (b) applying (dispensing, depositing, spraying, or coating) the paste to a surface of a PEM or a porous carbon electrode substrate (carbon paper) of an electro-conductive porous material to make a catalyst film (normally having a layer thickness of from 3 to 30 μm), (c) heating and drying the film, and (d) applying a solid polymer electrolyte solution to the catalyst film so that the film is impregnated with the electrolyte. Alternatively, the process comprises applying a paste made of catalyst particles, PTFE particles, and a solid polymer electrolyte solution to a PEM or a porous carbon electrode substrate to make a catalyst film and then heating and drying the film. The solid polymer electrolyte solution may be obtained by dissolving the same composition as the aforementioned ion-exchange membrane (PEM) in an alcohol. PTFE particles are typically supplied with in a solution with the particles dispersed therein. PTFE particles typically have a particle diameter of approximately 0.2-0.3 μm. Catalyst particles are typically Pt or Pt/Ru nano particles supported on carbon black particles.

The aforementioned solid polymer electrolyte-catalyst composite electrode has the following drawbacks: The solid polymer electrolyte-catalyst composite electrode has a high electrical resistivity, which may be explained as follows. When catalyst particles are mixed with solid polymer electrolyte solution to prepare a paste, the catalyst particles are covered with solid polymer electrolyte film having extremely low electronic conductivity (10⁻¹⁶−10⁻¹³ S/cm). Upon completion of a film-making process to prepare an electrode, pores 32 and the non-conductive solid polymer electrolyte 33 tend to separate or isolate catalyst particles 33. The formation of a continuous catalyst particle passage (electron-conducting channel) is inhibited or interrupted, although a continuous solid electrolyte passage (proton-conducting channel) is maintained, as shown in the sectional view of electrode of FIG. 2.

Furthermore, by pressing the catalyst-electrolyte composite composition layer against the PEM layer to make a catalyst-coated membrane (CCM) or membrane electrode assembly (MEA), a significant amount of the carbon-supported catalyst particles tend to be embedded deep into the PEM layer (illustrated by the bottom portion of FIG. 2), making them inaccessible by electrons (if used as a cathode) or incapable of delivering electrons to the anode current collector (if used as an anode). As a result, the overall percent utilization of carbon-supported catalyst is significantly reduced.

As shown in the upper portion of FIG. 1, the electronically non-conducting solid electrolyte 22 also severs the connection between the otherwise highly conductive catalyst-supporting carbon particles 21 and the carbon fibers 25 in the electrode-catalyst backing layer (carbon paper). This problem of solid electrolyte being interposed between a carbon particle and a carbon fiber is very significant and has been largely ignored by fuel cell researchers. The degree of severity of this problem is best illustrated by considering a three-layer model shown in FIG. 3. The model consists of top, core, and bottom layers that are electrically connected in series. The top layer represents a carbon fiber material, the bottom layer a carbon black particle material, and the core layer a solid electrolyte material. The total resistance (R_(S)), equivalent resistivity (ρ_(s)), and conductivity (σ_(s)) of the three-layer model can be easily estimated. For the top layer (carbon fiber), the properties or parameters are given as follows: conductivity (σ₁), resistivity (ρ₁), resistance (R₁), and thickness (t₁). Similar notations are given for the other two layers with subscript being “2” and “3”, respectively. FIG. 3 shows that the equivalent conductivity of the resulting three-layer model is ρ_(s)=(ρ₁t₁+ρ₂t₂+ρ₃t₃)/(t₁+t₂+t₃). With t₁=10 μm, t₂=1 μm, and t₃=30 nm (0.03 μm), ρ₁=10⁻¹ Ωcm, ρ₂=10⁺¹⁴ Ωcm, and ρ₃=10⁺² Ωcm, we have σ_(s)=1/ρs˜10⁻¹³ S/cm. Assume that the electrolyte layer has a thickness as low as 1 nm (0.001 μm), the equivalent conductivity would be still as low as σ_(s)≈10⁻¹⁰ S/cm. It is clear that the equivalent conductivity of the local electrode environment (three-component model) is dictated by the low conductivity or high resistivity of the solid electrolyte (22 in FIGS. 1 and 33 in FIG. 2). These shockingly low conductivity values (10⁻¹³ to 10⁻¹⁰ S/cm) clearly have been overlooked by all of the fuel cell researchers. It could lead to significant power loss (Ohmic resistance) in a fuel cell.

To effectively address the aforementioned issues associated with electro-catalysts in a fuel cell in general and a PEM-type fuel cell in particular, we decided to take a novel approach to the formulation of electro-catalysts. Rather than using the same solid electrolyte material as the PEM layer (which is ion-conductive but must be electronically non-conductive), we used a solid electrolyte material (that is both electron-conductive and ion-conductive) to coat, impregnate, and/or embed catalyst particles, which are un-supported or supported on conductive particles like carbon black. This newly developed ion- and electron-conductive electrolyte material is also herein after referred to as a coating material. The solid electrolyte layer (e.g., PEM or other ion conductive solids, organic or inorganic) interposed between the anode and the cathode remained to be an ion-conductive (e.g., proton-conductive), but not electron-conductive. As a result, the electrons produced at the anode can be quickly collected through the gas diffuser layer (carbon paper or cloth) and the protons produced at the anode can be quickly transported to and through the solid electrolyte membrane (PEM layer) without producing significant Ohmic losses. Similarly, the electrons that move around the external circuit and come back to the cathode side can reach the cathode catalyst particles without much resistance and the protons that have transported through the PEM layer also can easily reach the catalyst particle sites. With oxygen molecules diffusing through pores or the thin coating material layer being present, the cathode chemical reactions can readily proceed. In essence, the presently invented electrode that contains an ion- and electron-conductive material helps to form two networks of charge transport paths, one for electrons and the other for protons.

Hence, one of the preferred embodiments of the present invention is a process that utilizes a specially formulated electro-catalyst composition to produce a fuel cell electrode. The composition comprises: (a) a catalyst un-supported or supported on an electronically conducting solid carrier (e.g., carbon black particles) and (b) an ion-conducting material in physical contact with the catalyst, coated on the catalyst, and/or coated on a surface of the carrier, wherein the ion-conducting material is also electronically conducting with an electronic conductivity no less than 10⁻⁴ S/cm (preferably no less than 10⁻² S/cm) and ion (proton) conductivity no less than 10⁻⁵ S/cm (preferably no less than 10⁻³ S/cm). The catalyst may be selected from commonly used transition metal-based catalysts such as Pt, Pd, Ru, Mn, Co, Ni, Fe, Cr, and their alloys, mixtures, and oxides (these are given as examples and should not be construed as limiting the scope of the present invention). Such a composite catalyst (comprising supported or unsupported catalyst particles and the ion- and electron-conductive coating material) can be attached to or coated on a porous carbon paper on one side and attached to or coated on a PEM layer on another side (FIG. 4). This ion-conductive and electron-conductive material preferably comprises a polymer, which can be a homo-polymer, co-polymer, polymer blend or mixture, a semi-interpenetrating network, or a polymer alloy. In this case, one polymer component can be ion-conductive and another one electron-conductive. It is also possible that a polymer itself is conductive to both electrons and ions (e.g., protons). Examples will be given for these cases. The process itself will be described at a later section.

With this invented catalyst composition, the resulting electrode can be used as either an anode or a cathode. As shown in FIG. 4, when it is used in an anode, hydrogen gas or organic fuel can permeate to the electrode through the pores 23 or diffuse through the ion- and electron-conductive electrolyte material 44, which is ultra-thin and can be readily migrated through via diffusion. Due to its high electronic conductivity, the electrons produced at the catalyst particles 21 can be quickly transported through the electrolyte material 44 to carbon fibers 25 of a carbon paper and be collected with little resistance or resistive (Ohmic) loss. The produced protons are also capable of migrating through the invented ion- and electron-conductive electrolyte material 44 (herein after also referred to as the coating or impregnation material) into the electronically non-conductive PEM layer, which is a conventional solid electrolyte layer interposed between an anode and a cathode.

If used as a cathode catalyst material, this solid electrolyte coating material 44 allows the electrons that come from the external load to go to the catalyst particle sites where they meet with protons and oxygen gas to form water. The protons come from the anode side, through the PEM layer, and the coating material 44 to reach the catalyst sites. Oxygen gas migrates through the pores 23 or the electrolyte coating material 44 via diffusion. Again, the electrons are capable of being transported into the cathode without any significant Ohmic loss due to the high electronic conductivity of electrolyte material 44.

In one preferred embodiment, the ion-conductive and electron-conductive coating material 44 comprises a polymer that is by itself both ion-conductive and electron-conductive. Examples of this type polymer are sulfonated polyaniline compositions, as described by Epstein, et al. (U.S. Pat. No. 5,137,991, Aug. 11, 1992):

where 0≦y≦1, R₁, R₂, R₃, R₄, R₅, and R₆ are independently selected from the group consisting of H, SO₃ ⁻, SO₃H, —R₇SO₃ ⁻, —R₇SO₃H, —OCH₃, —CH₃, —C₂H₅, —F, —Cl, —Br, —I, —OH, —O⁻, —SR₇, —OR₇, —COOH, —COOR₇, —COR₇, —CHO, and —CN, wherein R₇ is a C₁-C₈ alkyl, aryl, or aralkyl group, and wherein the fraction of rings containing at least one R₁, R₂, R₃, or R₄ group being an SO₃ ⁻, SO₃H, —R₇SO₃ ⁻, or —R₇SO₃H that varies from approximately 20% to 100%. It may be noted that this class of polymers was developed for applications that made use of their electronic properties. Due to their high electronic conductivity, these polymers cannot be used as a PEM interposed between an anode and a cathode in a fuel cell (PEM must be electronically non-conductive to avoid internal short-circuiting in a fuel cell). Hence, it is no surprise that the proton conductivity of these polymers has not been reported by Epstein, et al.

It is of interest at this juncture to re-visit the issue of ion and electron conductivities for this coating material. The proton conductivity of a conventional PEM material is typically in the range of 10⁻³ S/cm to 10⁻¹ S/cm (resistivity ρ of 10¹ Ω-cm to 10³ Ω-cm). The thickness (t) of a PEM layer is typically in the vicinity of 100 μm and the active area is assumed to be A=100 cm². Then, the resistance to proton flow through this layer will be R=ρ(t/A)=10⁻³Ω to 10⁻¹Ω. Further assume that the resistance of the catalyst coating material (the ion- and electron-conductive material) will not add more than 10% additional resistance, then the maximum resistance of the coating layer will be 10⁻⁴Ω to 10⁻²Ω. With a coating layer thickness of 1 μm, the resistivity to proton flow cannot exceed 10² Ω-cm to 10⁴ Ω-cm (proton conductivity no less than 10⁻⁴ S/cm to 10⁻² S/cm). With an intended coating layer thickness of 0.1 μm (100 nm), the proton conductivity should be no less than 10⁻⁵ S/cm to 10⁻³ S/cm.

Similar arguments may be used to estimate the required electronic conductivity of the coating layer. Consider that the electrons produced at the catalyst surface have to pass through a coating layer (0.1 μm or 100 nm thick) and a carbon paper layer (100 μm in thickness with average transverse conductivity of 10⁻¹ S/cm to 10⁺¹ S/cm). A reasonable requirement is for the coating layer to produce a resistance to electron flow that is comparable to 10% of the carbon paper resistance. This implies that the electronic conductivity of the coating material should be in the range of 10⁻³ S/cm to 10⁻¹ S/cm. These values can be increased or decreased if the coating thickness is increased or decreased. It may be further noted that conventional PEM materials have an electronic conductivity in the range of 10⁻¹⁶-10⁻¹³ S/cm, which could produce an enormous power loss.

We therefore decided to investigate the feasibility of using sulfonated polyaniline (S—PANi) materials as a component of an electro-catalyst material. After an extensive study, we have found that the most desirable compositions for use in practicing the present invention are for R₁, R₂, R₃, and R₄ group in Formula I being H, SO₃ ⁻ or SO₃H with the latter two varied between 30% and 75% (degree of sulfonation between 30% and 75%). The proton conductivity of these SO₃ ⁻- or SO₃H-based S—PANi compositions increases from 3×10⁻³ S/cm to 4×10⁻² S/cm and their electron conductivity decreases from 0.5 S/cm to 0.1 S/cm when the degree of sulfonation is increased from approximately 30% to 75% (with y being approximately 0.4-0.6). These ranges of ion and proton conductivities are reasonable, particularly when one realizes that only a very thin film of S—PANi is used (typically much thinner than 1 μm and can be as thin as nanometers). A polymer of this nature can be used alone as an ion- and electron-conductive material. We have further found that these polymers are soluble in a wide range of solvents and are chemically compatible (miscible and mixable) with the commonly used proton-conductive polymers such as those represented by Formula IV-VII, to be described later. Hence, these S—PANi polymers also can be used in combination with an ion- (proton-) conductive polymer to coat the electro-catalyst particles.

The aforementioned class of S—PANi was prepared by sulfonating selected polyaniline compositions after polymer synthesis. A similar class of soluble aniline polymer could be prepared by polymerizing sulfonic acid-substituted aniline monomers. The synthesis procedures 26 are similar to those suggested by Shimizu, et al. (U.S. Pat. No. 5,589,108, Dec. 31, 1996). The electronic conductivity of this class of material was found by Shimizu, et al. to be between 0.05 S/cm and 0.2 S/cm, depending on the chemical composition. However, proton conductivity was not measured or reported by Shimizu, et al. We have found that the proton conductivity of this class of polymers typically ranges from 4×10⁻³ S/cm to 5×10⁻² S/cm, depending on the degree of sulfonation. It appears that both ion (proton) and electron conductivities of these polymers are well within acceptable ranges to serve as an ion- and electron-conductive polymer for use in the presently invented fuel cell catalyst compositions. Again, these polymers are soluble in a wide range of solvents and are chemically compatible (miscible and mixable) with commonly used proton-conductive polymers such as those represented by Formula IV-VII, to be described later. Hence, these polymers not only can be used alone as an ion- and electron-conductive polymer, but also can be used an electron-conductive polymer component that forms a mixture with a proton-conductive polymer.

The needed ion- and electron-conducting coating polymer can be a mixture or blend of an electrically conductive polymer and an ion-conductive polymer with their ratio preferably between 20/80 to 80/20. The electron-conductive polymer component can be selected from any of the π electron conjugate chain polymers, doped or un-doped, such as derivatives of polyaniline, polypyrrole, polythiophene, polyacetylen, and polyphenylene provided they are melt- or solution-processable. A class of soluble, electron-conductive polymers that can be used in the present invention has a bi-cyclic chemical structure represented by Formula II:

wherein R₁ and R₂ independently represent a hydrogen atom, a linear or branched alkyl or alkoxy group having 1 to 20 carbon atoms, a primary, secondary or tertiary amino group, a trihalomethyl group, a phenyl group or a substituted phenyl group, X represents S, O, Se, Te or NR₃, R₃ represents a hydrogen atom, a linear or branched alkyl group having 1 to 6 carbon atoms or a substituted or unsubstituted aryl group, providing that the chain in the alkyl group of R₁, R₂, or R₃, or in the alkoxy group of R₁ or R₂ optionally contains a carbonyl, ether or amide bond, M represents H⁺, an alkali metal ion such as Na⁺, Li⁺, or K⁺ or a cation such as a quaternary ammonium ion, and m represents a numerical value in the range between 0.2 and 2. This class of polymers was developed for the purpose of improving solubility and processability of electron-conductive polymers (Saida, et al., U.S. Pat. No. 5,648,453, Jul. 15, 1997). These polymers are also soluble in a wide range of solvents (including water) and are chemically compatible (miscible and mixable) with the proton-conductive polymers represented by Formula IV-VII, to be described later. These polymers exhibit higher electronic conductivity when both R₁ and R₂ are H, typically in the range of 5×10⁻² S/cm to 1.4 S/cm. These polymers are also proton-conductive (proton conductivity of 5×10⁻⁴ S/cm to 1.5×10⁻² S/cm) and hence can be used in the presently invented catalyst composition, alone or in combination with another ion-conductive or electron-conductive polymer.

Polymers which are soluble in water and are electronically conductive may be prepared from a monomer that has, as a repeat unit, a thiophene or pyrrole molecule having an alkyl group substituted for the hydrogen atom located in the beta position of the thiophene or pyrrole ring and having a surfactant molecule at the end of the alkyl chain (Aldissi, et al., U.S. Pat. No. 4,880,508, Nov. 14, 1989):

In these polymers, the monomer-to-monomer bonds are located between the carbon atoms which are adjacent to X, the sulfur or nitrogen atoms. The number (m) of carbon atoms in the alkyl group may vary from 1 to 20 carbon atoms. The surfactant molecule consists of a sulfonate group (Y=SO₃), or a sulfate group (Y=SO₄), or a carboxylate group (Y=CO₂), and hydrogen (A=H) or an alkali metal (A=Li, Na, K, etc.). Synthesis of these polymers may be accomplished using the halogenated heterocyclic ring compounds 3-halothiophene or 3-halopyrrole as starting points; these are available from chemical supply houses or may be prepared by method known to those skilled in the art. The electronic conductivity of these polymers is typically in the range of 10⁻³ S/cm to 50 S/cm.

The ion- or proton-conductive polymer can be any polymer commonly used as a solid polymer electrolyte in a PEM-type fuel cell. These PEM materials are well-known in the art. One particularly useful class of ion-conductive polymers is the ion exchange membrane material having sulfonic acid groups. These materials are hydrated when impregnated with water, with hydrogen ion H⁺ detached from sulfonic ion, SO₃ ⁻. The general structure of the sulfonic acid membranes that have received extensive attention for use in fuel cells and are sold under the trade name Nafion® by E. I. du Pont Company is as follows:

where x and y are integers selected from 1 to 100,000, preferably from 1 to 20,000, most preferably from 100 to 10,000. A similar polymer that is also suitable for use as a PEM is given as:

Sulfonic acid polymers having a shorter chain between the pendant functional group (side group) and the main polymer backbone absorb less water at a given concentration of functional group in the polymer than do polymers having the general structure as shown by Formula IV and V. The concentration of functional group in the dry polymer is expressed as an equivalent weight. Equivalent weight is defined, and conveniently determined by standard acid-base titration, as the formula weight of the polymer having the functional group in the acid form required to neutralize one equivalent of base. In a more general form, this group of proton-conducting polymers may be represented by the formula:

where x and y are integers selected from 1 to 100,000, m is an integer selected from 0 to 10 and R is a functional group selected from the group consisting of H, F, Cl, Br, I, and CH₃.

Another class of PEM polymer suitable for use as an ion-conductive polymer in the present invention is characterized by a structure having a substantially fluorinated backbone which has recurring pendant groups attached thereto and represented by the general formula:

—O(CFR_(f)′)_(b)—(CFR_(f))_(a)—SO₃H  (Formula VII)

where a=0−3, b=0−3, a+b=at least 1, R_(f) and R_(f)′ are independently selected from the group consisting of a halogen and a substantially fluorinated alkyl group having one or more carbon atoms.

The above polymers have a detachable hydrogen ion (proton) that is weakly attached to a counter-ion (e.g., SO₃ ⁻), which is covalently bonded to a pendant group of the polymer. While the general structures shown above are representative of several groups of polymers of the present invention, they are not intended to limit the scope of the present invention. It would become obvious to those skilled in the art, from the relationships presented herein that other sulfonic acid functional polymers having pendant chains, sterically hindered sulfonate groups or the like would absorb some water and conduct protons. For instance, the derivatives and copolymers of the aforementioned sulfonic acid polymers, alone or in combination with other polymers to form polymer blends, may also be used as an ion-conductive material in the invented fuel cell catalyst composition. The aforementioned polymers were cited as examples to illustrate the preferred mode of practicing the present invention. They should not be construed as limiting the scope of the present invention.

In summary, the ion- or proton-conducting polymer component of the desired mixture may be selected from the group consisting of poly(perfluoro sulfonic acid), sulfonated poly (tetrafluoroethylene), sulfonated perfluoroalkoxy derivatives of polytetrafluoroethylene, sulfonated polysulfone, sulfonated poly(ether ketone), sulfonated poly(ether sulfone ketone), sulfonated poly(ether ether ketone), sulfonated polyimide, sulfonated styrene-butadiene copolymers, sulfonated polystyrene, sulfonated poly chloro-trifluoroethylene (PCTFE), sulfonated perfluoroethylene-propylene copolymer (FEP), sulfonated ethylene-chlorotrifluoroethylene copolymer (ECTFE), sulfonated poly vinylidenefluoride (PVDF), sulfonated copolymers of polyvinylidenefluoride with hexafluoropropene and tetrafluoroethylene, sulfonated copolymers of ethylene and tetrafluoroethylene (ETFE), polybenzimidazole (PBI), their chemical derivatives, copolymers, blends and combinations thereof. These materials have been used as solid electrolyte materials for various PEM-based fuel cells due to their relatively good proton conductivity (typically between 0.1 S/cm and 0.001 S/cm).

Any of these ion-conductive materials can be mixed with an electron-conductive polymer to make a polymer blend or mixture that will be conductive both electronically and ionically. Such a mixture is prepared preferably by dissolving both the ion-conductive polymer and the electron-conductive polymer in a common solvent to form a polymer solution. Catalyst particles are then added to this polymer solution to form a suspension, also referred to as a dispersion. Alternatively, catalyst particles may be dispersed in a liquid to obtain a suspension, which is then poured into the polymer solution to form a precursor composite catalyst composition. Nano-scaled catalyst particles may be selected from (but not limited to) commonly used transition metal-based catalysts such as Pt, Pd, Ru, Mn, Co, Ni, Fe, Cr, and their alloys or mixtures. They are commercially available in a fine powder form or in a liquid with these nano-scaled particles dispersed therein. They may be manufactured by a powder manufacturing method such as solution precipitation, sol-gel conversion, or spray-based powder production routes. The suspension containing dispersed catalyst particles (supported or unsupported) and a polymer or polymer mixture (both ion- and electron-conductive) may be coated (via dispensing, spraying, ink-jet printing, screen printing, painting, or brushing, etc.) onto a primary surface of a gas diffuser plate (electrically conductive electrode-backing layer such as a carbon paper or carbon cloth sheet). Upon removal of the liquid medium, the remaining ingredients form an electrode that is connected to this gas diffuser plate. Alternatively, the suspension may be deposited to one or both primary surfaces of a solid electrolyte membrane to produce a catalyst-coated membrane (CCM). With two diffuser plates sandwiching this CCM we have a membrane-electrode assembly (MEA).

Electro-catalyst particles used in the presently invented process and composition can be one of three types or their combinations: (1) unsupported catalyst particles; (2) supported catalysts, such as aggregate particles of carbon black supporting Pt particles; (3) nano-particles. Unsupported catalyst particles are catalyst particles that are not supported on the surface of another material. These include such materials as platinum black and platinum/ruthenium black which in their natural form are not necessarily nano-scaled in size. Supported catalysts include a catalytically active species dispersed on a support phase. Thus, one or more highly dispersed active species phases, typically metal or metal oxide clusters or crystallites, with dimensions on the order of about 0.5 nanometers to 10 nanometers that are dispersed over the surface of larger support particles (typically 10 nm to 1 μm). The support particles can be aggregated to form larger aggregate particles. For example, the support particles can be chosen from a metal oxide. (e.g., RuO₂, In₂O₃, ZnO, IrO₂, SiO₂, Al₂O₃, CeO₂, TiO₂ or SnO₂), aerogels, xerogels, carbon or a combination of the foregoing. Carbon black particles are popular materials for supporting the dispersed catalytically active species.

Catalyst nano-particles are particles which have an average size of not greater than 100 nanometers (preferably smaller than 10 nanometers), and may be unsupported. The nano-particles most preferably have an average size of from about 0.5 to 2 nanometers. Catalyst nano-particles may comprise metals, metal oxides, metal carbides, metal nitrides or any other material that exhibits catalytic activity.

Hence, as one preferred embodiment, the presently invented fuel cell electrode-producing process comprises (a) preparing a suspension of catalyst particles dispersed in a liquid medium containing a polymer dissolved or dispersed therein; (b) dispensing the suspension onto a primary surface of a substrate selected from an electronically conductive catalyst-backing layer (gas diffuser plate) or a solid electrolyte membrane; and (c) removing the liquid medium to form the electrode that is connected to or integral with the substrate, wherein the polymer is both ion-conductive and electron-conductive and the polymer forms a coating in physical contact with the catalyst particles or coated on the catalyst particles. Again, the presently invented electrode that contains an ion- and electron-conductive coating material helps to form two networks of charge transport paths, one for electrons and the other for protons.

Alternatively, the electro-catalyst particles may be produced in-situ by delivering the suspension that contains molecular precursors along with other ingredients to a substrate (e.g., a surface of a carbon paper or PEM layer) and converting the precursors to the catalytically active species after deposition via heating, UV curing, or a radiation-induced reaction. Hence, another preferred embodiment of the present invention is a process that comprises: (a) preparing a suspension or solution comprising a liquid medium, a molecular metal precursor and a polymer dissolved or dispersed in the liquid medium; (b) dispensing the suspension or solution onto a primary surface of a substrate (an electronically conductive catalyst-backing layer or a solid electrolyte membrane layer); and (c) converting the molecular metal precursor to catalyst particles and removing the liquid medium to form the electrode that is connected to or integral with the substrate, wherein the polymer is both ion-conductive and electron-conductive with an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm and the polymer forms a coating in physical contact with the catalyst particles or coated on the catalyst particles.

A molecular metal precursor is a metal-containing molecular compound, comprising preferably a metal such as platinum, ruthenium, palladium, silver, nickel, cobalt, iron, manganese, or gold. For example, molecular precursors such as hydrogen hexachloroplatinate, ruthenium chloride hydrate, hydrogen hexachloropallidate, silver nitrate, nickel acetate or potassium tetra-chloroaurate can be reduced to form nano-scaled catalyst particles. The reducing agent can be any number of alcohols, diols or other reducing compounds such as methanol, ethanol, n-propanol, 2-propanol, n-butanol, 2-butanol, ethylene glycol, formaldehyde or N,N-dimethyl formamide. The particles are stabilized from aggregation by the adsorption of stabilizing polymer molecules on the particle surfaces. We have found that most of the aforementioned ion- and electron-conductive polymers or polymer mixtures can be dissolved in alcohol (methanol, ethanol, n-propanol, 2-propanol, n-butanol, 2-butanol), mixture of alcohol+water, ethylene glycol, formaldehyde or N,N-dimethyl formamide, which are also good reducing agents. We are also pleasantly surprised to find that these ion- and electron-conductive polymers are excellent stabilizing agents. These observations are highly significant since the resulting suspension or solution can be very simple in chemical composition: a liquid medium (e.g., alcohol), an ion- and-electron-conductive polymer (e.g., sulfonated polyaniline), and a molecular metal precursor (e.g., hydrogen hexachloroplatinate). Carbon black particles can be added to serve as a support for the converted catalyst. These particles are well-stabilized by the dissolved polymer.

Preferred metals for the supported electro-catalytically active species include noble metals, particularly Pt, Ag, Pd, Ru, Os and their alloys. The metal phase can also include a metal selected from the group Ni, Rh, Ir, Co, Cr, Mo, W, V, Nb, Al, Ta, Ti, Zr, Hf, Zn, Fe, Cu, Ga, In, Si, Ge, Sn, Y, La, lanthanide metals and combinations or alloys of these metals. Preferred metal alloys include alloys of Pt or Pd with other metals, such as Ru, Os, Cr, Ni, Mn, Fe, and Co. Particularly preferred among these is PtRu for use in the DMFC anode and PtCrCo or PtNiCo for use in the cathode.

Alternatively, metal oxide-carbon electro-catalyst particles that include a metal oxide active species dispersed on a carbon support phase may be used. The metal oxide can be selected from the oxides of the transition metals, preferably those existing in oxides of variable oxidation states, and most preferably from those having an oxygen deficiency in their crystalline structure. For example, the metal oxide-based catalytically active species can be an oxide of a metal selected from the group consisting of Au, Ag, Pt, Pd, Ni, Co, Rh, Ru, Fe, Mn, Cr, Mo, Re, W, Ta, Nb, V, Hf, Zr, Ti or Al. A particularly preferred metal oxide active species is manganese oxide (MnO_(x), where x is 1 to 2). The supported active species can include a mixture of different oxides, solid solutions of two or more different metal oxides or double oxides. The metal oxides can be stoichiometric or non-stoichiometric and can be mixtures of oxides of one metal having different oxidation states.

In a particularly preferred embodiment, the molecular metal precursors are selected from low temperature precursors, such as those that have a relatively low decomposition or conversion temperature. The term molecular metal precursor refers to a molecular compound that includes a metal atom. Examples include organo-metallics (molecules with carbon-metal bonds), metal organics (molecules containing organic ligands with metal-to-nonmetal bonds) and inorganic compounds such as metal nitrates, metal halides and other metal salts. The molecular metal precursor compounds that eliminate ligands by a radical mechanism upon conversion to metal are preferred, especially if the species formed are stable radicals and therefore lower the decomposition temperature of that precursor compound. Therefore, preferred precursors to metals used for conductors are carboxylates, alkoxides or combinations thereof that convert to metals, metal oxides or mixed metal oxides by eliminating small molecules such as carboxylic acid anhydrides, ethers or esters. Metal carboxylates, particularly halogenocarboxylates such as fluorocarboxylates, are particularly preferred metal precursors due to their high solubility

Particularly preferred molecular metal precursor compounds are metal precursor compounds containing silver, nickel, platinum, gold, palladium, cobalt, iron, manganese, copper and ruthenium. In one preferred embodiment of the present invention, the molecular metal precursor compound comprises platinum. Various molecular precursors can be used for platinum metal. Preferred molecular precursors for platinum include nitrates, carboxylates, beta-diketonates, and compounds containing metal-carbon bonds. Divalent platinum (II) complexes are particularly preferred. Preferred molecular precursors also include ammonium salts of platinates such as ammonium hexachloro platinate (NH₄)₂ PtCl₆, and ammonium tetrachloro platinate (NH₄)₂PtCl₄; sodium and potassium salts of halogeno, pseudohalogeno or nitrito platinates such as potassium hexachloro platinate K₂PtCl₆, sodium tetrachloro platinate Na₂PtCl₄, potassium hexabromo platinate K₂PtBr₆, potassium tetranitrito platinate K₂Pt(NO₂)₂; dihydrogen salts of hydroxo or halogeno platinates such as hexachloro platinic acid H₂PtCl₆, hexabromo platinic acid H₂PtBr₂, dihydrogen hexahydroxo platinate H₂Pt(OH)₂; diammine and tetraammine platinum compounds such as diammine platinum chloride Pt(NH₃)₂Cl₂, tetraammine platinum chloride [Pt(NH₃)₄]Cl₂, tetraammine platinum hydroxide [Pt(NH₃)₄](OH)₂, tetraammine platinum nitrite [Pt(NH₂)₄](NO₂)₂, tetrammine platinum nitrate Pt(NH₂)₄(NO₃)₂, tetrammine platinum bicarbonate [Pt(NH₃)₄](HCO₃)₂, tetraammine platinum tetrachloroplatinate [Pt(NH₃)₄]PtCl₄; platinum diketonates such as platinum (II) 2,4-pentanedionate Pt(C₅ H₇ O₂)₂; platinum nitrates such as dihydrogen hexahydroxo platinate H₂ Pt(OH)₂ acidified with nitric acid; other platinum salts such as Pt-sulfite and Pt-oxalate; and platinum salts comprising other N-donor ligands such as [Pt(CN)₂]⁴⁺.

Platinum precursors useful in organic-based ink suspension compositions include Pt-carboxylates or mixed carboxylates. Examples of carboxylates include Pt-formate, Pt-acetate, Pt-propionate, Pt-benzoate, Pt-stearate, Pt-neodecanoate. Other precursors useful in organic ink composition include aminoorgano platinum compounds including Pt(diaminopropane) (ethylhexanoate). Preferred combinations of platinum precursors and solvents include: PtCl₄ in H₂O; Pt-nitrate solution from H₂Pt(OH)₆; H₂Pt(OH)₆ in H₂O; H₂PtCl₆ in H₂O; and [Pt(NH₂)₄](NO₃)₂ in H₂O.

Additional examples of molecular metal precursor materials are metal porphyrin complexes which catalyze the reduction of O₂ to OH⁻ but are oxidized during the oxidation of OH⁻. Included in this group are metal porphyrin complexes of Co, Fe, Zn, Ni, Cu, Pd, Pt, Sn, Mo, Mn, Os, Ir and Ru. Other metal ligand complexes can be active in these catalytic oxidation and reduction reactions and can be formed by the methods described herein. Such metal ligands can be selected from the class of N₄-metal chelates, represented by porphyrins, tetraazaanulens, phtalocyanines and other chelating agents. In some cases the organic ligands are active in catalyzing reduction and oxidation reactions. In some cases the ligands are active when they remain intact, as might be the case for an intact porphyrin ring system, or they might be partially reacted during thermal processing to form a different species that could also be active in the catalytic reactions. An example is the reaction product derived from porphyrins or other organic compounds.

Molecular metal precursors with decomposition temperatures below about 300° C. allow the formation of catalyst particles coated with an ion- and electron-conductive coating on a substrate such as a PEM layer or a sheet of carbon paper. This enables the liquid medium, a molecular metal precursor and a conducting polymer to be processed at low temperatures to form the desired electrode structure. In one embodiment, the conversion temperature is not greater than about 250° C., such as not greater than about 200° C., more preferably is not greater than about 150° C. and even more preferably is not greater than about 100° C. The conversion temperature is the temperature at which the metal species contained in the molecular metal precursor compound is substantially (at least 95 percent) converted to the pure metal.

A very significant feature of the present invention is the notion that the presence of an ion- and electron-conductive polymer affords us an exceptionally high degree of freedom in processing fuel cell electrodes, catalyst-coated membranes, and membrane-electrode assemblies without having to worry about such issues as disrupting the electron-conducting path or burying the carbon-supported catalyst particles deep into the PEM layer (which is otherwise not electron-conductive). We are free to dispense the suspension to and form an electrode on either a primary surface of a carbon paper sheet or a PEM film. The resulting coating material, being both ion- and electron-conductive, provides a bridge to establish two networks of charge transport. This feature also allows us to laminate PEM, electrode, and diffuser layers together to form an MEA with a wide processing window (e.g., the lamination pressure can be higher without inducing the detrimental effect of incapacitating a significant proportion of catalyst particles by, for instance, burying them too deep into a PEM layer). The features of simple catalyst suspension compositions and ease of producing electrodes also enables the mass-production of MEAs on a continuous basis using a highly advantageous roll-to-roll process, explained as follows:

Referring to FIG. 8( a), as a preferred embodiment, the invented process may include feeding a solid electrolyte membrane 34 intermittently or continuously from a feed roller 32. Two liquid dispensers 36, 38 are employed to deliver a suspension from each side of membrane 34 onto its two primary surfaces (top and bottom surfaces shown in this figure). By removing the liquid medium from the suspension, one obtains catalytic electrodes 40, 42 that are connected to the two respective primary surfaces of the membrane to form a three-layer catalyst-coated membrane (CCM). At the same time, gas diffuser layers 46, 48 (continuous sheets of carbon paper or cloth) are fed from two sets of rollers, 44 a, 44 b and 44 c, 44 d, to sandwich the CCM layer to form a membrane-electrode assembly 50 a or 50 b, which is being pulled or supported by a set of rollers 49 a, 49 b. A cutting device may be provided to slice the MEA 50 b into individual MEA pieces for use in a fuel cell system.

Alternatively, referring to FIG. 8( b), as another preferred embodiment, the invented process may include feeding a solid electrolyte membrane 34 intermittently or continuously from a feed roller 32. Two liquid dispensers 36, 38 are employed to deliver a suspension onto a primary surface of a gas diffuser layer, 46 or 48. By removing the liquid medium from the suspension, one obtains catalytic electrodes 40, 42 that are connected to the two respective primary surfaces of the diffuser layers 46, 48. At the same time, catalytic electrode-coated gas diffuser layers 46, 48 are fed from two sets of rollers, 44 a, 44 b and 44 c, 44 d, to sandwich the membrane layer 34 to form a membrane-electrode assembly 50 a or 50 b, which is being pulled or supported by a set of rollers 49 a, 49 b. A cutting device may be provided to slice the MEA 50 b into individual MEA pieces for use in a fuel cell system.

Another alternative arrangement, schematically shown in FIG. 8( c), entails a roll-to-roll process that begins with feeding a solid electrolyte membrane 34 intermittently or continuously from a feed roller 32. Two liquid dispensers 36, 38 are employed to deliver a suspension from each side of membrane 34 onto its two primary surfaces (top and bottom surfaces shown in this figure). By removing the liquid medium from the suspension, one obtains catalytic electrodes 40, 42 that are connected to the two respective primary surfaces of the membrane to form a three-layer catalyst-coated membrane 52. This CCM may be wound around a take-up roller 54 for later uses. Such a process also allows for mass production of CCMs which are commonly regarded as the most difficult fuel cell components to produce with consistent quality. The presently invented electro-catalyst composition ensures that two intertwine networks of charge transport for electrons and ions (e.g., protons) are always preserved, relatively independent of the actual processing conditions.

Hence, as one preferred embodiment, the presently invented fuel cell electrode-producing process comprises (a) preparing a first suspension of first catalyst particles dispersed in a first liquid medium containing a first polymer dissolved or dispersed therein; (b) dispensing the first suspension onto a primary surface of a substrate selected from an electronically conductive catalyst-backing layer (gas diffuser plate) or a solid electrolyte membrane; (c) removing the liquid medium to form the electrode that is connected to or integral with the substrate, wherein the polymer is both ion-conductive and electron-conductive and the polymer forms a coating in physical contact with the catalyst particles or coated on the catalyst particles; (d) dispensing a second suspension to a second primary surface of the substrate (or to a primary surface of a second substrate such as a second carbon paper layer), wherein the second suspension comprises second catalyst particles dispersed in a second liquid medium containing a second polymer dissolved or dispersed therein; and (e) removing the second liquid medium to form an electrode connected to the second primary surface of the substrate (or connected to a primary surface of the second substrate), wherein the second polymer is both ion-conductive and electron-conductive with an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm and the polymer forms a coating in physical contact with the second catalyst particles or coated on the second catalyst particles.

If the substrate is a solid electrolyte membrane, the process is essentially what is described in FIG. 8( a). If the substrates are two separate gas diffuser layers, the process is essentially what is described in FIG. 8( b). In each process, the catalytic electrode layers 40, 42 can be obtained from (a) a suspension containing catalyst particles dispersed in a liquid medium or (b) a suspension containing a molecular metal precursor dissolved or dispersed in a liquid medium. In the latter case, a heating, energy, and/or radiation treatment may be utilized to induce a chemical reaction or physical transition for converting the precursor to nano-scaled catalyst particles, unsupported or supported on a conducting particle phase.

In a particularly preferred embodiment, the process may involve including a pore-forming means to produce pores in the resulting electrode. Pore-forming means are well known in the art. For instance, physical or chemical blowing or foaming agents commonly used in the production of foamed plastics can be incorporated in the suspension. Alternatively, aero gel forming techniques may be used to produce a high level of porosity in the resulting electrode wherein a large number of interconnected pores are formed with pore walls being sub-micron or nanometer in size and, hence, the catalyst particles are readily accessible by the fuel (e.g., hydrogen gas) and oxidant (oxygen gas) that diffuse through these pores. These pore walls are both ion- and electron-conductive.

A suspension can be prepared to contain only an ion- and proton-conductive polymer (or a mixture of two or three polymers) dissolved or dispersed in a solvent. Such a catalyst-free suspension is also a useful material that can be coated to a primary surface of a carbon paper or a primary surface of a solid PEM layer. This is followed by depositing a thin film of the presently invented coated catalyst particles (composite electro-catalyst composition) from a suspension onto either the carbon paper or the PEM layer. Such a catalyst-free coating serves to ensure that the coated catalysts will have a complete electronic connection with the carbon paper and complete ionic connection with the PEM layer. The resulting electrode is characterized in that the carbon black along with the supported Pt nano-particles are not surrounded by the electronically non-conductive PEM polymer after lamination to form a membrane-electrode assembly.

Therefore, another preferred embodiment of the present invention is a process of producing a fuel cell electrode on a substrate selected from a gas diffuser layer (e.g., carbon paper or cloth) or a solid electrolyte membrane. The process comprises (a) preparing a first suspension or solution of a first liquid medium containing a first ion- and electron-conductive polymer dissolved or dispersed therein; (b) dispensing this first suspension or solution onto the substrate and removing the first liquid to form a layer of first conductive polymer adhered to the substrate; and (c) depositing a catalyst composition onto the first conductive polymer with the catalyst composition being bonded to, mixed with or integral with the first conductive polymer to form the electrode. This electrode is characterized in that it comprises catalyst particles coated with or in physical contact with a conductive phase comprising the first conductive polymer and that this conductive phase has an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm.

This step of depositing a catalyst composition may comprise (i) dispensing a second suspension of a second liquid medium with catalyst particles dispersed therein and a second ion- and electron-conductive polymer dissolved or dispersed therein and (ii) removing the second liquid to form the catalyst composition wherein the second conductive polymer has an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm. This second conductive polymer may be the same material as the first conductive polymer. Alternatively, this second conductive polymer may be mixed with the first conductive polymer during the deposition step to form the cited conductive phase.

Further alternatively, this step of depositing a catalyst composition may comprise (i) dispensing a second suspension of a second liquid medium with a molecular metal precursor dispersed or dissolved therein and a second ion- and electron-conductive polymer dissolved or dispersed therein and (ii) converting the precursor to catalyst particles and removing the second liquid to form the catalyst composition wherein the second conductive polymer has an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm. This second conductive polymer may be the same material as the first conductive polymer. Alternatively, this second conductive polymer may be mixed with the first conductive polymer during the deposition step to form the cited conductive phase.

It may be noted that a roll-to-roll process has been suggested in the prior art for producing a catalyst-coated membrane or a membrane electrode assembly; e.g., as described in Bonsel, et al. (U.S. Pat. No. 6,197,147, Mar. 6, 2001) and Starz, et al. (U.S. Pat. No. 6,500,217, Dec. 31, 2002). However, these prior art processes did not make use of a catalyst composition capable of producing bi-networks of charge transport paths and, hence, the produced CCMs or MEAs still had low catalyst utilization efficiency.

EXAMPLE 1 Preparation of poly(alkyl thiophene) as an Electron-Conductive Component

Water-soluble conductive polymers having a thiophene ring (X=sulfur) and alkyl groups containing 4, 6, 8, and 10 carbon atoms (m=4, 6, 8, or 10) in Formula III were prepared, according to a method adapted from Aldissi, et al. (U.S. Pat. No. 4,880,508, Nov. 14, 1989). The surfactant molecules of these polymers were sulfonate groups with sodium, hydrogen, or potassium. Conductivity of polymers of this invention in a self-doped state was from about 10⁻³ to about 10⁻² S/cm. When negative ions from a supporting electrolyte used during synthesis were allowed to remain in the polymer, conductivities up to about 50 S/cm were observed. Conductivities of polymers without negative ions from a supporting electrolyte which were doped with vaporous sulfuric acid were about 10² S/cm.

A doped poly(alkyl thiophene) (PAT) with Y=SO₃H and A=H in Formula III that exhibited an electron conductivity of 12.5 S/cm was dissolved in water. A sulfonated poly(ether ether ketone)(PEEK)-based material called poly(phthalazinon ether sulfone ketone) (PPESK) was purchased from Polymer New Material Co., Ltd., Dalian, China. With a degree of sulfonation of approximately 93%, this polymer was soluble in an aqueous hydrogen peroxide (H₂O₂) solution. A water solution of 3 wt. % poly(alkyl thiophene) and an aqueous H₂O₂ solution of 3 wt. % sulfonated PPESK was mixed at several PPESK-to-PAK ratios and stirred at 70° C. to obtain several polymer blend solution samples.

Samples of poly(alkyl thiophene)-PPESK mixtures in a thin film form were obtained by casting the aforementioned solutions onto a glass plate, allowing water to evaporate. The proton and electron conductivity values of the resulting solid samples were then measured at room temperature. The results were shown in FIG. 5, which indicates that good electron and proton conductivities can be obtained within the range of 30-75% PPESK.

EXAMPLE 2 Inks (Suspensions) Containing poly(alkyl thiophene), PPESK, Carbon Black-Supported Pt or Pt/Ru

Carbon black-supported Pt and Pt/Ru catalyst particles were separately added and dispersed in two aqueous polymer blend solutions prepared in Example 1. The PPESK-to-PAK ratio selected in both solutions was 1:1. The viscosity of the resulting solutions (more properly referred to as suspensions or dispersions) was adjusted to vary between a tooth paste-like thick fluid and a highly dilute “ink”, depending upon the amount of water used. These suspensions can be applied to a primary surface of a carbon paper or that of a PEM layer (e.g. Nafion or sulfonated PEEK sheet) via spraying, printing (inkjet printing or screen printing), brushing, or any other coating means.

A suspension comprising carbon black-supported Pt particles dispersed in an aqueous solution of PPESK and PAK was brushed onto the two primary surfaces of a Nafion sheet with the resulting catalyst-coated membrane (CCM) being laminated between two carbon paper sheets to form a membrane electrode assembly (MEA). In this case, the electrode was characterized in that the carbon black along with the supported Pt nano-particles were coated by or embedded in an ion- and electron-conductive polymer blend. A similar MEA was made that contained conventional Nafion-coated catalyst particles, wherein Nafion is only ion-conductive, but not electron-conductive. The two MEAs were subjected to single-cell polarization testing with the voltage-current density curves shown in FIG. 6. It is clear that coating the catalyst particles with an electron- and ion-conductive polymer mixture significantly increases the voltage output of a fuel cell compared with that of a conventional fuel cell with Nafion-coated catalysts. This implies a more catalyst utilization efficiency and less power loss (lesser amount of heat generated).

EXAMPLE 3 Sulfonated polyaniline (S—PANi)

The chemical synthesis of the S—PANi polymers was accomplished by reacting polyaniline with concentrated sulfuric acid. The procedure was similar to that used by Epstein, et al. (U.S. Pat. No. 5,109,070, Apr. 28, 1992). The resulting S—PANi can be represented by Formula I with R₁, R₂, R₃, and R₄ group being H, SO₃ ⁻ or SO₃H with the latter two being varied between 30% and 75% (degree of sulfonation between 30% and 75%). The proton conductivity of these SO₃ ⁻- or SO₃H-based S—PANI) compositions was in the range of 3×10⁻³ S/cm to 4×10⁻² S/cm and their electron conductivity of 0.1 S/cm to 0.5 S/cm when the degree of sulfonation was from approximately 30% to 75% (with y being approximately 0.4-0.6).

A sample with the degree of sulfonation of about 65% was dissolved in 0.1 M NH₄OH up to approximately 20 mg/ml. A small amount of carbon-supported Pt was added to the S—PANi solution to obtain a suspension that contained approximately 5% by volume of solid particles. The suspension was sprayed onto the two primary surfaces of a Nafion sheet with the resulting catalyst-coated membrane (CCM) being laminated between two carbon paper sheets to form a membrane electrode assembly (MEA). Prior to this lamination step, one surface of the carbon paper, the one facing the catalyst, was pre-coated with a thin layer of S—PANi via spraying of the S—PANi solution onto the paper surface and allowing the solvent to evaporate under a chemical fume hood. The resulting electrode was characterized in that the carbon black along with the supported Pt nano-particles were coated by or embedded in an ion- and electron-conductive polymer. The electrode was also porous, providing channels for fuel or oxidant transport. A similar MEA was made that contained conventional Nafion-coated catalyst particles, wherein Nafion is only ion-conductive, but not electron-conductive. The two MEAs were subjected to single-cell polarization testing with the voltage-current density curves shown in FIG. 7. These results demonstrate that coating the catalyst particles with an electron- and ion-conductive polymer significantly increases the voltage output of a fuel cell compared with that of a conventional fuel cell with Nafion-coated catalysts.

EXAMPLE 4 Bi-Cyclic Conducting Polymers

The preparation of conductive polymers represented by Formula II having H for both R₁ and R₂, S for X, and H⁺ for M was accomplished by following a procedure suggested by Saida, et al. (U.S. Pat. No. 5,648,453, Jul. 15, 1997). These polymers exhibit electronic conductivity in the range of 5×10⁻² S/cm to 1.4 S/cm and proton conductivity of 5×10⁻⁴ S/cm 1.5×10⁻² S/cm.

Six polymer blends were prepared from such a bi-cyclic polymer (electron conductivity σ_(e)=1.1 S/cm and proton conductivity σ_(p)=3×10⁻³ S/cm) and approximately 50% by wt. of the following proton-conductive polymers: poly(perfluoro sulfonic acid) (PPSA), sulfonated PEEK (S—PEEK), sulfonated polystyrene (S—PS), sulfonated PPESK, sulfonated polyimide (S—PI), and sulfonated polyaniline (S—PANi). The conductivities of the resulting polymer blends are σ_(e)=0.22 S/cm and σ_(p)=2×10⁻² S/cm for (bi-cyclic+PPSA), σ_(e)=0.2 S/cm and σ_(p)=7×10⁻³ S/cm for (bi-cyclic+S—PEEK), σ_(e)=0.23 S/cm and σ_(p)=5.5×10⁻³ S/cm for (bi-cyclic+S—PS), σ_(e)=0.19 S/cm and σ_(p)=6×10⁻³ S/cm for (bi-cyclic+S—PPESK), σ_(e)=0.21 S/cm and σ_(p)=7.5×10⁻³ S/cm for (bi-cyclic+S—PI), and σ_(e)=0.75 S/cm and σ_(p)=3×10⁻³ S/cm for (bi-cyclic+S—PANi), These conductivity values are all within the acceptable ranges for these polymer blends to be a good coating material for the catalyst particles in a fuel cell electrode.

EXAMPLE 5 Suspension Comprising a Molecular Metal Precursor

Preferred molecular precursors include chloroplatinic acid (H₂PtCl₆—H₂O), tetraamineplatinum (II) nitrate (Pt(NH₃)₄(NO₃)₂, tetraamineplatinum (II) hydroxide (Pt(NH₃)₄(OH)₂), tetraamineplatinum (II) bis(bicarbonate) (Pt(NH₃)₄(HCO₃)₂), platinum nitrate (Pt(NO₃)₂), hexa-hydroxyplatinic acid (H₂Pt(OH)₆), platinum (II) 2,4-pentanedionate (Pt(acac)₂), and platinum (II) 1,1,1,5,5,5-hexafluoro 2,4-pentanedionate (Pt(hfac)₂). Other platinum precursors include Pt-nitrates, Pt-amine nitrates, Pt-hydroxides, Pt-carboxylates, Na₂PtCl₄, and the like. Typically, the Pt precursor was dissolved in either water or organic-based solvent up to 30% by weight concentration.

Using water solution as an example, chloroplatinic acid (H₂PtCl₆—H₂O) was dissolved in water for up to 15% by weight. On a separate basis, an aqueous ethanol solution of 3% by weight sulfonated polyaniline was prepared. The two solution was mixed together to form a suspension which was stirred for 30 minutes. This suspension was divided up into two beakers with one of them being added with carbon black particles to serve as a catalyst support. A desired quantity of each suspension was cast onto a primary surface of each of two sheets of carbon paper to produce an electrode-coated carbon paper (or carbon paper-backed electrode). A Nafion film was then sandwiched between the two carbon paper-supported electrodes to form a membrane electrode assembly. A molecular precursor conversion temperature of 250° C. was used to produce the catalyst particles. Actually, both chloroplatinic acid (H₂PtCl₆—H₂O) and hexa-hydroxyplatinic acid (H₂Pt(OH)₆) can be decomposed at a temperature lower than 150° C. while tetraamineplatinum (II) nitrate (Pt(NH₃)₄(NO₃)₂, tetraamineplatinum (II) hydroxide (Pt(NH₃)₄(OH)₂), tetraamineplatinum (II) bis(bicarbonate) (Pt(NH₃)₄(HCO₃)₂), and platinum nitrate (Pt(NO₃)₂) can be decomposed at a temperature lower than 300° C. It may be note that polyaniline-based polymers are stable up to 350° C. and, hence, the precursor conversion step would not adversely affect the structure of these conductive polymers. In some cases, the removal of the reaction product gases (e.g., NH₃) naturally leave behind pores in the electrode, which is a desirable feature since pores facilitate diffusion of fuel (hydrogen) and oxidant gases (oxygen).

EXAMPLE 6 The Preparation of Particles Including an Alloy of Palladium and Nickel

Palladium and nickel wires were subjected to a twin-wire arc-based nano particle production process. A high pulse current of 240 amps was used to create the arc. The Pd and Ni atoms in the vaporous phase collided and condensed to form nano particles of approximately 2-5 nm in size.

In addition, for the purpose of comparison, an aqueous solution was prepared including nickel and palladium as dissolved nitrates. The total of the metals in the mixture is 5 weight percent. The nickel and palladium were proportioned at 30/70 Pd/Ni by weight. The solution was sonicated for 30 minutes to ensure uniformity. A single transducer ultrasonic generator was then used to produce an aerosol, which was sent to a furnace at a temperature of 900° C. where particles were produced. The aerosol carrier gas comprises 95 percent nitrogen by volume and 5 percent hydrogen by volume. The resulting particles have a size range of 4 nm to 10 nm.

Palladium and its alloys were particularly useful anode catalysts for direct formic acid fuel cell.

EXAMPLE 7 Production of a Membrane Electrode Assembly

The reaction between 1,3-divinyl-1,1,3,3-tetramethyldisiloxane and hexachloroplatinic acid led to Pt-based nano particles. The liquid reaction product contain approximately 18 wt.-% of platinum herein referred to as Pt—VTS. Pt—VTS can be decomposed at a relatively low temperature, e.g. by drying at a temperature of 110° C. Extremely finely divided, metallic platinum remained while the silicon content of the vinyl-substituted siloxanes could no longer be detected in the finished catalyst layers. Other suitable complex compounds of the precious metals iridium, ruthenium and palladium for use in practicing the present invention are dodecacarbonyltetrairidium (Ir₄(CO)₁₂), (η⁶-benzene)(ρ⁴-cyclohexadiene)ruthenium(0) ((η⁶-C₆H₆)Ru(η⁴-1,3-C₆H₈)) and bis(dibenzylideneacetone)-palladium(0).

The reaction product Pt—VTS was prepared following the procedure suggested by U.S. Pat. No. 3,775,452. For instance, 20 parts by weight sodium carbonate were added to a mixture of 10 parts by weight H₂PtCl₆.8H₂O, 20 parts by weight 1,3-divinyl-1,1,3,3-tetramethyldisiloxane and 50 parts by weight ethanol. The mixture was boiled for 15 minutes and then a solution of solfonated polyaniline in ethanol-water and Vulcan XC72 carbon black were added to the boiling mixture. The resulting suspension was subjected to sonification for 30 minutes and then dispensed and deposited onto two primary surfaces of a Nafion-115 film to produce a catalyst-coated membrane, which was then sandwiched between two sheets of carbon paper to produce a membrane-electrode assembly. 

1. A process for producing a fuel cell electrode, said process comprising: (a) preparing a first suspension of first catalyst particles dispersed in a first liquid medium containing a first polymer dissolved or dispersed therein; (b) dispensing said first suspension onto a first primary surface of a substrate selected from a first electronically conductive catalyst-backing layer or a solid electrolyte membrane; and (c) removing said liquid medium to form a first electrode connected to or integral with said substrate, wherein said polymer is both ion-conductive and electron-conductive with an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm and said polymer forms a coating in physical contact with said catalyst particles or coated on said catalyst particles.
 2. The process as defined in claim 1, wherein said electronic conductivity is no less than 10⁻² S/cm and said ion conductivity is no less than 10⁻³ S/cm.
 3. The process as defined in claim 1, wherein said polymer comprises a mixture of an electronically conductive polymer and a proton-conducting polymer selected from the group consisting of poly(perfluoro sulfonic acid), sulfonated polytetrafluoroethylene, sulfonated perfluoroalkoxy derivatives of polytetrafluoroethylene, sulfonated polysulfone, sulfonated poly(ether ketone), sulfonated poly(ether sulfone ketone), sulfonated poly(ether ether ketone), sulfonated polystyrene, sulfonated polyimide, sulfonated styrene-butadiene copolymers, sulfonated poly chloro-trifluoroethylene, sulfonated perfluoroethylene-propylene copolymer, sulfonated ethylene-chlorotrifluoroethylene copolymer, sulfonated polyvinylidenefluoride, sulfonated copolymers of polyvinylidenefluoride with hexafluoropropene and tetrafluoroethylene, sulfonated copolymers of ethylene and tetrafluoroethylene (ETFE), polybenzimidazole (PBI), their chemical derivatives, copolymers, blends and combinations thereof.
 4. The process as defined in claim 1, wherein said polymer comprises an electronically conducting polymer.
 5. The process as defined in claim 1, wherein said polymer comprises an electronically conducting polymer selected from the group consisting of sulfonated polyaniline, sulfonated polypyrrole, sulfonated poly thiophene, sulfonated bi-cyclic polymers, their derivatives, and combinations thereof.
 6. The process as defined in claim 1, wherein said polymer comprises a mixture of an ion-conducting polymer and an electron-conducting polymer.
 7. The process as defined in claim 1, wherein said polymer comprises an ion-conducting polymer which is also electronically conducting.
 8. The process as defined in claim 1 wherein said catalyst particles are selected from the group consisting of unsupported catalyst particles, supported catalysts, nano-particles, and combinations thereof.
 9. The process of claim 1 wherein said catalyst particles comprise a catalytically active transition metal supported on a carbon particle.
 10. The process as defined in claim 1 wherein said catalyst particles comprise a catalytically active material selected from the group consisting of transition metals, transition metal alloys, transition metal oxides, transition metal carbides, transition metal nitrides, and combinations thereof.
 11. The process as defined in claim 1 wherein said catalyst particles comprise a catalytically active material selected from the group consisting of Pt, Ag, Pd, Ru, Os, Ni, Rh, Ir, Co, Cr, Mo, W, V, Nb, Al, Ta, Ti, Zr, Hf, Zn, Fe, Cu, Ga, In, Si, Ge, Sn, Y, La, lanthanide metals, and mixtures, alloys, and oxides of these metals.
 12. A process for producing a fuel cell electrode, said process comprising: (a) preparing a first suspension or solution comprising a first liquid medium, a first molecular metal precursor and a first polymer dissolved or dispersed in said first liquid medium; (b) dispensing said first suspension or solution onto a first primary surface of a substrate selected from a first electronically conductive catalyst-backing layer or a solid electrolyte membrane; and (c) converting said first molecular metal precursor to catalyst particles and removing said first liquid medium to form a first electrode connected to or integral with said substrate, wherein said first polymer is both ion-conductive and electron-conductive with an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm and said polymer forms a coating in physical contact with said catalyst particles or coated on said catalyst particles.
 13. The process of claim 12 wherein said step of converting comprises a heat-, ultraviolet, and/or radiation-induced chemical reaction.
 14. The process of claim 12 wherein said catalyst particles comprise a catalytically active material selected from the group consisting of Pt, Ag, Pd, Ru, Os, Ni, Rh, Ir, Co, Cr, Mo, W, V, Nb, Al, Ta, Ti, Zr, Hf, Zn, Fe, Cu, Ga, In, Si, Ge, Sn, Y, La, lanthanide metals, and mixtures, alloys, and oxides of these metals.
 15. The process of claim 12 wherein said suspension or solution further comprises a particulate 21 support material and said catalyst particles comprise catalytically active, nano-scaled particles supported on said support material.
 16. The process of claim 12 further comprising pore-forming means and said electrodes comprise pores.
 17. The process of claim 16 wherein said pore-forming means comprises using and activating a blowing or foaming agent or producing an aerogel.
 18. The process of claim 12 wherein said polymer comprises a mixture of an electronically conductive polymer and a proton-conducting polymer selected from the group consisting of poly(perfluoro sulfonic acid), sulfonated polytetrafluoroethylene, sulfonated perfluoroalkoxy derivatives of polytetrafluoroethylene, sulfonated polysulfone, sulfonated poly(ether ketone), sulfonated poly(ether sulfone ketone), sulfonated poly(ether ether ketone), sulfonated polyimide, sulfonated styrene-butadiene copolymers, sulfonated polychlorotrifluoroethylene, sulfonated perfluoroethylene-propylene copolymer, sulfonated ethylene-chlorotrifluoroethylene copolymer, sulfonated polystyrene, sulfonated polyvinylidenefluoride, sulfonated copolymers of polyvinylidenefluoride with hexafluoropropene and tetrafluoroethylene, sulfonated copolymers of ethylene and tetrafluoroethylene, polybenzimidazole, their chemical derivatives, copolymers, blends, and combinations thereof.
 19. The process of claim 12 wherein said polymer comprises an electronically conducting polymer.
 20. The process of claim 12, wherein said polymer comprises an electronically conducting polymer selected from the group consisting of sulfonated polyaniline, sulfonated polypyrrole, sulfonated poly thiophene, sulfonated bi-cyclic polymers, their derivatives, and combinations thereof.
 21. The process of claim 12 wherein said first molecular metal precursor comprises a metal-containing molecular compound selected from the group consisting of organo-metallics with at least a carbon-metal bond; metal organics containing at least an organic ligand with a metal-to-non-metal bond; and inorganic compounds selected from metal nitrates, metal halides, carboxylates, alkoxides, ammonium salts of platinates, complex compounds of platinum, iridium, ruthenium and palladium, and metal salts of platinum, iridium, ruthenium and palladium; and combinations thereof.
 22. The process of claim 12 wherein said catalyst particles comprise a catalytically active material selected from the group consisting of Pt, Ag, Pd, Ru, Os, Ni, Rh, Ir, Co, Cr, Mo, W, V, Nb, Al, Ta, Ti, Zr, Hf, Zn, Fe, Cu, Ga, In, Si, Ge, Sn, Y, La, lanthanide metals, and mixtures, alloys, and oxides of these metals.
 23. The process of claim 1 wherein said substrate is a solid electrolyte membrane intermittently or continuously supplied from a feed roller and said process further comprises: (d) dispensing a second suspension to a second primary surface of said substrate, wherein said second suspension comprises second catalyst particles dispersed in a second liquid medium containing a second polymer dissolved or dispersed therein; and (e) removing said second liquid medium to form a second electrode connected to the second primary surface of said substrate, wherein said second polymer is both ion-conductive and electron-conductive with an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm and said polymer forms a coating in physical contact with said second catalyst particles or coated on said second catalyst particles; wherein the first electrode, the solid electrolyte membrane and the second electrode form a catalyst-coated membrane.
 24. The process of claim 23 further comprising a step of bringing a sheet of electrically conductive fuel diffuser plate onto the electrode connected to said first primary surface of the membrane and bringing a sheet of oxidant diffuser plate onto the electrode connected to the second primary surface of the membrane to form a membrane-electrode assembly.
 25. The process of claim 12 wherein said substrate is a solid electrolyte membrane intermittently or continuously supplied from a feeder roller and said process further comprises: (d) dispensing a second suspension to a second primary surface of said substrate, wherein said second suspension comprises a second molecular metal precursor dispersed or dissolved in a second liquid medium containing a second polymer dissolved or dispersed therein; and (e) converting said second molecular precursor to second catalyst particles and removing said second liquid medium to form a second electrode connected to the second primary surface of said substrate, wherein said second polymer is both ion-conductive and electron-conductive with an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm and said polymer forms a coating in physical contact with said second catalyst particles or coated on said second catalyst particles; wherein said first electrode, said solid electrolyte membrane, and said second electrode form a catalyst-coated membrane.
 26. The process of claim 25 further comprising a step of bringing a sheet of electrically conductive fuel diffuser plate onto one surface of said catalyst-coated membrane and bringing a sheet of oxidant diffuser plate onto another surface of said catalyst-coated membrane to form a membrane-electrode assembly.
 27. The process of claim 1 wherein said substrate is a first gas diffuser sheet intermittently or continuously supplied from a first feeder roller and said process further comprises: (d) feeding, intermittently or continuously, a second gas diffuser sheet from a second feeder roller; (e) dispensing a second suspension to a primary surface of said second diffuser sheet, wherein said second suspension comprises second catalyst particles dispersed in a second liquid medium containing a second polymer dissolved or dispersed therein; (f) removing said second liquid medium to form an electrode connected to said primary surface of said second diffuser sheet, wherein said second polymer is both ion-conductive and electron-conductive with an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm and said polymer forms a coating in physical contact with said second catalyst particles or coated on said second catalyst particles; and (g) feeding a sheet of solid electrolyte membrane between the electrode of said first diffuser sheet and the electrode of said second diffuser sheet to form a membrane-electrode assembly.
 28. The process of claim 12 wherein said substrate is a first gas diffuser sheet intermittently or continuously supplied from a first feeder roller and said process further comprises: (d) feeding, intermittently or continuously, a second gas diffuser sheet from a second feeder roller; (e) dispensing a second suspension to a primary surface of said second diffuser sheet, wherein said second suspension comprises a second molecular metal precursor dissolved or dispersed in a second liquid medium containing a second polymer dissolved or dispersed therein; (f) converting said second molecular metal precursor to second catalyst particles and removing said second liquid medium to form an electrode connected to said primary surface of said second diffuser sheet, wherein said second polymer is both ion-conductive and electron-conductive with an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm and said polymer forms a coating in physical contact with said second catalyst particles or coated on said second catalyst particles; and (g) feeding a sheet of solid electrolyte membrane between the electrode of said first diffuser sheet and the electrode of said second diffuser sheet to form a membrane-electrode assembly.
 29. The process of claim 16 wherein said pore-forming means comprises forming aero gels with pore walls comprising said ion- and electron-conducting polymer and said catalyst particles in said walls.
 30. A process of producing a fuel cell electrode on a substrate selected from a gas diffuser layer or a solid electrolyte membrane, said process comprising (a) preparing a first suspension or solution of a first liquid medium containing a first ion- and electron-conductive polymer dissolved or dispersed therein; (b) dispensing said first suspension or solution onto said substrate and removing said first liquid to form a layer of said first conductive polymer adhered to said substrate; and (c) depositing a catalyst composition onto said first conductive polymer with said catalyst composition being bonded to, mixed with or integral with said first conductive polymer to form said electrode characterized in that said electrode comprises catalyst particles coated with or in physical contact with a conductive phase comprising said first conductive polymer and that said conductive phase has an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm.
 31. The process of claim 30 wherein said step of depositing a catalyst composition comprises (i) dispensing a second suspension of a second liquid medium with catalyst particles dispersed therein and a second ion- and electron-conductive polymer dissolved or dispersed therein and (ii) removing said second liquid to form said catalyst composition wherein said second conductive polymer has an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm.
 32. The process of claim 30 wherein said step of depositing a catalyst composition comprises (i) dispensing a second suspension of a second liquid medium with molecular metal precursor dispersed or dissolved therein and a second ion- and electron-conductive polymer dissolved or dispersed therein and (ii) converting said precursor to catalyst particles and removing said second liquid to form said catalyst composition wherein said second conductive polymer has an electronic conductivity no less than 10⁻⁴ S/cm and ionic conductivity no less than 10⁻⁵ S/cm. 